Alexander Mikhailovsky,

1
Basics of femtosecond laser spectroscopy
Alexander Mikhailovsky, Optical Characterization
Facility CoordinatorInstitute for Polymer and
Organic SolidsDepartment of Chemistry and
Biochemistry, University of CA Santa
BarbaraSanta Barbara, CA 93106
mikhailovsky_at_chem.ucsb.edu, (805)893-2327
2
Whats so Special About Femtosecond Lasers???

• Short optical pulse.
• Most of energy dissipation and transfer
  processes occur on the time scale larger than
  100 fs.
• Femtosecond laser pulses enable one to excite
  the species studied instantly (texcltlt trel)
• Dynamics of the excited state can be monitored
  with high temporal resolution ( 0.5 tpulse
  12-50 fs for most of commercial lasers)
• Visualization of ultrafast dynamical processes
  (fluorescence, excited state absorption)

• High peak power of the light
• I J/tpulse,, I Power, J pulse energy.
• 1 mJ pulse with 10 ns duration - 0.1 MW
• 1 mJ pulse with 100 fs duration - 10 GW
• Non-linear spectroscopy and materials
  processing (e.g., multi-photon absorption,
  optical harmonics generation, materials
  ablation, etc.)

W. Kaiser, ed., Ultrashort Laser Pulses
Generation and Applications, Springer-Verlag,Ber
lin, 1993
3
How to Prepare a Femtosecond Pulse I
Femtosecond laser pulses are usually Fourier
transform-limited pulses
DwDt 2p
Dw 2p/Dt
Large spectral bandwidth for short pulses
Dl l2 /(cDt)
Dl 21 nm for 100 fs pulses with l0 800 nm
fs pulse
Large bandwidth limits the choice of the
laseractive medium (broad-band materials
only,e.g., TiSapphire, laser dyes) and laser
cavitydesign (no bandwidth limiting elements,
such asnarrowband mirrors)
ns pulse
Wavelength
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How to Prepare a Femtosecond Pulse II
Laser mode combination of frequency (w)and
direction (k) of the electromagnetic waveallowed
by the laser cavity geometry.
L
The spectrum of laser modes is not continuous ln
2L/n
Laser pulse as a sum of modes
Lock
Relative phase of the modes has to beconstant
(locked) in order to obtain a stableoutput pulse

No lock
Time
5
Passive Mode-Locking
Saturating absorber technique
Initial noise seed
Steady-state operation
Time
Time
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Passive Mode-Locking II
Kerr-lens mode-locking

• Kerrs effect inetnsity-dependent indexof
  refraction n n0 n2I
• The e/m field inside the laser cavity
  hasGaussian distribution of intensity
  whichcreates similar distribution of the
  refractiveindex.
• High-intensity beam is self-focused by the
  photoinduced lens.

Low-intensity
High-intensity

• High-intensity modes have smaller cross-section
  and are less lossy. Thus, Kerr-lens is similar
  to saturating absorber!
• Some lasing materials (e.g. TiSapphire) can act
  as Kerr-media
• Kerrs effect is much faster than saturating
  absorber allowing one generate very short
  pulses (5 fs).

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Group Velocity Dispersion (GVD)
Optical pulse in a transparent medium stretches
because of GVD

• v c / n speed of light ina medium
• n depends on wavelength, dn/dl lt 0 normal
  dispersion

• Because of GVD, red components (longer
  wavelengths) of the pulse propagatefaster than
  blue components (shorter wavelengths) leading to
  pulse stretching (aka chirp).
• Uncompensated GVD makes fs laser operation
  impossible
• GVD can be compensated by material with abnormal
  dispersion

8
GVD Compensation
GVD can be compensated if optical pathlength is
different for blue and red components of the
pulse.
Diffraction grating compensator
Prism compensator
Wavelength tuning mask
Red component of the pulse propagates in glass
more than the blue one and has longer optical
path (n x L).
If OR RR gt OB, GVD lt 0
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Typical fs Oscillator
Typical TiSapphire fs Oscillator Layout

• Tuning range 690-1050 nm
• Pulse duration gt 5 fs (typically 50 -100 fs)
• Pulse energy lt 10 nJ
• Repetition rate 40 1000 MHz
• (determined by the cavity length)
• Pump source
• Ar-ion laser (488514 nm)
• DPSS CW YAG laser (532 nm)
• Typical applications time-resolved emission
  studies, multi-photon absorption spectroscopy
  and imaging

O. Zvelto, Principles of lasers, Plenum, NY
(2004)
10
Amplification of fs Pulses
Due to high intensity, fs pulses can not be
amplified as is.

• Recipe for the amplification
• Chirped pulse amplifier (CPA)
• Stretch the pulse in time, thus reducing the
  peak power (I J / tpulse !) (typically the
  pulse is stretched up to hundreds of ps)
• Amplify the stretched pulse
• Compress the pulse

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Pulse Stretcher

• Pulse stretcher utilizes the same principle as
  compressor separation of spectral components
  and manipulation with their delays
• Compressor can converted into stretcher by
  addition of focusing opticsflipping paths of
  red and blue components.

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Regenerative Amplifier
Cavity dumping
PC
PC
Injection of the pulse from stretcher (FP film
polarizer, PC Pockels cell), Pockels cell
rotates polarization of theseeding pulse
FP
FP
Amplification
Ejection of the pulse into compressor
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Typical CPA

• Repetition rate 1 KHz
• Pulse duration 50-150 fs
• Pulse energy 1 mJ
• Wavelength usually fixed close to 800nm
• Typical applications pumping optical
  frequency converters, non-linear spectroscopy,
  materials processing

14
Frequency Conversion of fs Pulses
With fs pulses non-linear optical processes are
very efficient due to highintensity of input
light Iout A Iinm
Parametric down-conversion
Optical harmonic generation
Second harmonic
Non-linearcrystal
Signal
1/lSH 2/lF kSH 2 kF
ls
lp
Pump 800 nm, 1mJ, 100 fs SHG 400 nm, 0.2 mJ
Idler
li
1/lp 1/ls 1/li kp ks ki
Harmonic generation can be used to upconvert
signal or idler into the visible range ofspectrum
Pump 800 nm, 1mJ, 100 fs Signal 1100 -1600 nm,
0.12 mJ Idler 1600 3000 nm, 0.08 mJ
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Femtosecond Continuum
White-light continuum generation

• Self-focusing and self-phase-modulation broadens
  the spectrum
• Extremely broad-band, ultrafast pulses (Vis and
  IR ranges)
• Strongly chirped

1. R. L. Fork et al, 8 Opt.Lett., p. 1, (1983)

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OCF Femtosecond Equipment

• Fs oscillator (SP Tsunami)
• 700-980 nm, tpulse gt 75 fs, lt 10 nJ, 80 MHz
  repetition rate
• Regenerative amplifier (SP Spitfire)
• 800 nm, tpulse gt 110 fs, 1 mJ, 1 kHz repetition
  rate
• Seeded by Tsunami
• Optical parametric amplifier (SP OPA-800C)
• 1100 3000 nm, lt 0.15 mJ, tpulse gt 130 fs
• Pumped by Spitfire
• Harmonic generation devices provide ultrashort
  pulses tunable inthe range 400 1500 nm
• Pulse energy lt 50 mJ

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Two-Photon Absorption
Degenerate case
b TPA cross-section, c concentration of
material
1PA
TPA
Beers Law
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TPA Cross-Section Units
Is not it a bit complicated?
Typical TPA absorption cross-section is 1 - 10 GM
Göppert-Mayer M., Ann.Physik 9, 273 (1931)
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Do We Really Need a Fs Pulse?
Accuracy limit of the most of intensity
measurements

• 10 GM c 10-4 M
• x 1 mm 1W 1018 phot/sec

I 16 GW/cm2
If beam diameter is 10 m, required lasers
power/pulse energy is
CW laser power 12000W
YAGNd laser (10 ns pulse, 25 Hz rep. rate) 120
mJ pulse energy (3 mW)
TiSapphire laser (100 fs pulse, 100 MHz rep.
rate), 1.2 nJ pulse energy (120 mW)
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TPA PL excitation

• Pros
• Very sensitive
• Easy to setup
• Works without amplifier

• Cons
• Works only for PL emitting materials
• Not absolute (requires reference material)

21
TPA PLE II
b TPA cross-section, c concentration, x
length of interaction, I laser light
intensity,A geometrical factor (usually
unknown)
TPA PL technique requires a reference measurement
for collimated beams
Good reference materials laser dyes
(Fluorescein, Rhodamin, Coumarin)
C. Xu and W. W. Webb, J. of Am. Opt. Soc. 13, 481
(1996)
22
TPA Measurements in Non-Fluorescent Materials
Z-Scan Technique
Sample
Lens
Intensityof light
Transmission of the sample
z
Open aperture Z-scan, TPA measurements
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Z-Scan Measurements of Kerrs Non-Linearity
Aperture
Sample
Z
Closed aperture Z-scan
DT

• Kerr lens focuses or defocuses light clipped
  by the aperture thus modulating its transmission

Z
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Summary on Z-scan

• Cons
• Z-scan works if the thickness of the sample is
  much smaller than the beams waist length.
• Data processing apparatus relies on the Gaussian
  profile of the beam. Very accurate
  characterization of the pump beam is required.
• Requires high energy pump pulses as well as high
  concentration of TPA absorber in order to
  achieve reasonable accuracy of the data.
• Artifacts are possible due to long-living
  excited state absorption.
• Pros
• Works with non-fluorescent materials
• Allows one to measure real part of high-ordrer
  susceptabilities

M. Sheik-Bahae et al, IEEE J. of Quantum
Electronics, 26(4), p. 760 (1990)
25
TPA Applications

• 3D optical memory
• 3D holographic gratings and
• photonic structures
• Remote sensing and hi-res imaging

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TPA Microfabrication

1. Photonic crystal
2. Magnified view of (a)
3. Tapered waveguide
4. Array of cantilevers

B.H. Cumpston et al., Nature 398, p. 51 (1999)
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TPA Imaging
l
Image from Heidelberg Universityweb-site
Two photonimaging (works even under the
surface!)
Single photonimaging
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Time-Resolved Emission Spectroscopy
Time-correlated photon countingtechniques
Dt
1ps
1ns
1ms
1ms
Single-shotmeasurements
PL up-conversion
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Single-Shot PL Decay Measurement
Sample
Beamsplitter

• Temporal resolution is limited by the
  detector(20 ns)
• Works best on amplified laser systems.
• Can collect the data in 1 shot of the laser.
  (In macroscopic systems)

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Time-Resolved Luminescence Experiments
Time-Correlated Single Photon Counting (TCSPC)
Beamsplitter
Sample
Start
Stop
Dt
360-470 nm 100fs
Fast PD
Filter
Laser
Luminescence
MCP PMT
Spectrometer
Start
PC
Stop
Correlator
Erdman R., Time Correlated Single Photon
Counting Fluorescence Spectroscopy,
Wiley-VCH, (2005)
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TCSPC

• Temporal resolution 50 ps.
• Excitation range 470 360 nm, emission range
  300 900 nm
• Works excellent on timescale lt 50 ns, on longer
  time-scales, data collection time may be quite
  long.
• Very sensitive, works well with low emission
  yield materials
• Resolution is limited by the jitter and width of
  detector response (The highest resolution is
  possible only with MCP PMT. Price tag 15K.
  Regular PMTs provide resolution about 1 ns.)

Why Single Photon counting?
Start
Stop2
Stop1
Pile-up effect
N
Luminescence
Laser
Dt
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TCSPC II
Acousto-optical pulse picker
RF

• If the time between laser pulsesis shorter or
  comparable with radiativelife-time of the
  sample, the chromophorcan be saturated
• Repetition rate (time between pulses)can be
  reduced (increased) by using apulse picker.
• Acousto-optical pulse picker uses controlled
  diffraction of laser pulses on a grating
  generated by ultrasound

Piezo transducer
Diffracted beam
Direct beam
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Luminescence Upconversion
Sample
SHG
100 fs, 800 nm
Gate pulsedelay
Spectrometer
Upconversioncrystal
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Luminescence Upconversion II
Upconversion process gating
PL
PL (vis)
Gate (NIR)
Signal (UV)
Dt
Pump
Gate

• Intensity of the signal is proportional to
  intensity of PL at the moment of the gating
  pulsearrival.
• Resolution is determined by the gating pulse
  duration
• High repetition rate and power lasers are
  required
• Works well with photostable materials
• Limited delay range (mechanical delay 15 cm 1
  ns)

1/ls 1/lPL 1/lG kS kPL kG IS IG IPL(Dt)
J. Shah, IEEE J. Quantum Electron. 24, p. 276,
1988
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Pump-Probe Experiments I
Idea of the experiment
Before excitation
0-1
After
Da
1-2
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Pump-Probe Experiments II

• PPE enable one to trace the relaxation dynamics
  with sub-100 fs resolution
• Types of the data generated by PPE
  time-resolved absorption spectra and absorption
  transients at a certain wavelength.
• Numerous combinations of pump and probe beams
  are possible (UV pump visible probe,
  UV-pumpcontinuum probe, etc.)
• High pump intensities are required in order to
  produce noticeable change in the optical
  absorption of the sample (GW/cm2 TW/cm2)
  (TiSapphire amplifiers are
• generally required)
• Interpretation of the data is sometimes
  complicated

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Pump-Probe Experiments III
Lock-inamplifier
SHG
100 fs, 800 nm
Probe pulsedelay
Spectrometer
Continuumgenerator

• Detects 10-5 transmission change
• PPE spectra can be chirp-corrected during the
  experiment
• Use of continuum as a probe enables one to cover
  the entire visible and NIR ranges

V.I. Klimov and D.W. McBranch, Opt.Lett. 23, p.
277, 1998
38
Semiconductor Quantum Dots
39
Transient Absorption Spectrscopy of CdSe Quantum
Dots
Klimov V.I. and McBranch D. W., Phys.Rev.Lett.
80, p. 4028, 1998